2024-03-26 16:15:02 +00:00
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/* Progressive Mesh type Polygon Reduction Algorithm
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*
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* 1998: Original version by Stan Melax (c) 1998
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* Permission to use any of this code wherever you want is granted..
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* Although, please do acknowledge authorship if appropriate.
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*
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* 2014: Code style upgraded to be more consistent with graphics/gamedev conventions. Relicensed as MIT/PD.
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* Stan Melax: "Yes, this code can be licensed with the same license as the original. That should be fine."
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*
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* 2020: C version by Cloud Wu (c) 2020. Licensed as MIT/PD.
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*/
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static inline void array_find_and_remove(array(int) arr, int v) {
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for( int i = 0, end = array_count(arr); i < end; i++ )
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if( arr[i] == v ) { array_erase_fast(arr, i); --end; break; }
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}
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#include <assert.h>
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#include <math.h>
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#include <stdlib.h>
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struct triangle_n {
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int vertex[3]; // the 3 points (id) that make this tri
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vec3 normal; // unit vector othogonal to this face
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};
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struct vertex {
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vec3 position; // location of point in euclidean space
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array(int) neighbor; // adjacent vertices
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array(int) face; // adjacent triangles
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int id; // place of vertex in original Array
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int collapse; // candidate vertex (id) for collapse
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float objdist; // cached cost of collapsing edge
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};
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struct mesh {
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struct vertex *v;
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struct triangle_n *t;
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int n_face;
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int n_vertex;
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};
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// array
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static inline struct vertex *Vertex(struct mesh *M, int id) { return M->v + id; }
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static inline struct triangle_n *Triangle(struct mesh *M, int id) { return M->t + id; }
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static inline struct triangle_n *Face(struct mesh *M, struct vertex *v, int idx) { return M->t + v->face[idx]; }
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static void AddVertex(struct mesh *M, const float *v) {
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int id = M->n_vertex++;
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struct vertex * tmp = Vertex(M, id);
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tmp->position = ptr3(v);
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tmp->neighbor = NULL;
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tmp->face = NULL;
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tmp->id = id;
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tmp->collapse = -1;
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tmp->objdist = 0;
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}
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static void RemoveVertex(struct mesh *M, int id) {
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struct vertex * v = Vertex(M, id);
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ASSERT(v->id == id);
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ASSERT(array_count(v->face) == 0);
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for (int i=0;i<array_count(v->face);i++) {
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struct vertex * nv = Vertex(M, v->face[i]);
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array_find_and_remove(nv->neighbor, id);
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}
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v->id = -1; // invalid vertex id
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array_free(v->neighbor);
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array_free(v->face);
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}
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static void ComputeNormal(struct mesh *M, struct triangle_n *t) {
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struct vertex * v0 = Vertex(M, t->vertex[0]);
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struct vertex * v1 = Vertex(M, t->vertex[1]);
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struct vertex * v2 = Vertex(M, t->vertex[2]);
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vec3 a = sub3(v1->position, v0->position);
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vec3 b = sub3(v2->position, v1->position);
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t->normal = norm3(cross3(a,b));
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}
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static void AddNeighbor(struct mesh *M, int vid, int id) {
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struct vertex *v = Vertex(M, vid);
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for (int i=0;i<array_count(v->neighbor);i++) {
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if (v->neighbor[i] == id)
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return;
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}
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array_push(v->neighbor, id);
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}
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static void AddTriangle(struct mesh *M, const int v[3]) {
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if (v[0] == v[1] || v[0] == v[2] || v[1] == v[2])
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return;
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ASSERT(v[0] < M->n_vertex);
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ASSERT(v[1] < M->n_vertex);
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ASSERT(v[2] < M->n_vertex);
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int id = M->n_face++;
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struct triangle_n * tmp = Triangle(M, id);
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tmp->vertex[0] = v[0];
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tmp->vertex[1] = v[1];
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tmp->vertex[2] = v[2];
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ComputeNormal(M, tmp);
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for(int i=0;i<3;i++) {
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struct vertex *obj = Vertex(M, v[i]);
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array_push(obj->face, id);
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}
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AddNeighbor(M, v[0], v[1]);
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AddNeighbor(M, v[0], v[2]);
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AddNeighbor(M, v[1], v[0]);
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AddNeighbor(M, v[1], v[2]);
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AddNeighbor(M, v[2], v[0]);
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AddNeighbor(M, v[2], v[1]);
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}
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static int HasVertex(struct triangle_n * t, int vid) {
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return (t->vertex[0] == vid || t->vertex[1] == vid || t->vertex[2] == vid);
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}
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static void RemoveIfNonNeighbor_(struct mesh *M, struct vertex *v, int id) {
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for (int i=0;i<array_count(v->neighbor);i++) {
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if (v->neighbor[i] == id) {
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for (int j=0;j<array_count(v->face);j++) {
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if (HasVertex(Face(M, v, j), id))
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return;
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}
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// remove from neighbors
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array_erase_fast(v->neighbor, i);
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return;
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}
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}
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}
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static void RemoveIfNonNeighbor(struct mesh *M, struct vertex *v0, struct vertex *v1) {
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if (v0 == NULL || v1 == NULL)
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return;
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RemoveIfNonNeighbor_(M, v0, v1->id);
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RemoveIfNonNeighbor_(M, v1, v0->id);
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}
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static void RemoveTriangle(struct mesh *M, int id) {
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struct triangle_n * face = Triangle(M, id);
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struct vertex * v[3];
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for (int i=0;i<3;i++) {
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v[i] = Vertex(M, face->vertex[i]);
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if (v[i]->id < 0)
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v[i] = NULL;
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else {
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array_find_and_remove(v[i]->face, id);
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}
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}
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RemoveIfNonNeighbor(M, v[0], v[1]);
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RemoveIfNonNeighbor(M, v[1], v[2]);
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RemoveIfNonNeighbor(M, v[2], v[0]);
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}
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static void ReplaceVertex(struct mesh *M, int faceid, int oldid, int newid) {
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struct triangle_n * face = Triangle(M, faceid);
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ASSERT(oldid >=0 && newid >= 0);
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ASSERT(HasVertex(face, oldid));
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ASSERT(!HasVertex(face, newid));
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if(oldid==face->vertex[0]){
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face->vertex[0]=newid;
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} else if(oldid==face->vertex[1]){
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face->vertex[1]=newid;
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} else {
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face->vertex[2]=newid;
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}
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struct vertex *vold = Vertex(M, oldid);
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struct vertex *vnew = Vertex(M, newid);
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array_find_and_remove(vold->face, faceid);
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array_push(vnew->face, faceid);
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RemoveIfNonNeighbor(M, vold, Vertex(M, face->vertex[0]));
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RemoveIfNonNeighbor(M, vold, Vertex(M, face->vertex[1]));
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RemoveIfNonNeighbor(M, vold, Vertex(M, face->vertex[2]));
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AddNeighbor(M, face->vertex[0], face->vertex[1]);
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AddNeighbor(M, face->vertex[0], face->vertex[2]);
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AddNeighbor(M, face->vertex[1], face->vertex[0]);
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AddNeighbor(M, face->vertex[1], face->vertex[2]);
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AddNeighbor(M, face->vertex[2], face->vertex[0]);
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AddNeighbor(M, face->vertex[2], face->vertex[1]);
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ComputeNormal(M, face);
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}
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static void MeshInit(struct mesh *M, int vert_n, int tri_n) {
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M->n_face = 0;
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M->n_vertex = 0;
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M->v = (struct vertex *)MALLOC(vert_n * sizeof(struct vertex));
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M->t = (struct triangle_n *)MALLOC(tri_n * sizeof(struct triangle));
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}
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static void MeshFree(struct mesh *M) {
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FREE(M->v);
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FREE(M->t);
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}
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static float ComputeEdgeCollapseCost(struct mesh *M, struct vertex *u, int vid) {
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// if we collapse edge uv by moving u to v then how
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// much different will the model change, i.e. how much "error".
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// Texture, vertex normal, and border vertex code was removed
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// to keep this demo as simple as possible.
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// The method of determining cost was designed in order
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// to exploit small and coplanar regions for
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// effective polygon reduction.
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// Is is possible to add some checks here to see if "folds"
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// would be generated. i.e. normal of a remaining face gets
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// flipped. I never seemed to run into this problem and
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// therefore never added code to detect this case.
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struct vertex *v = Vertex(M, vid);
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vec3 tmp = sub3(v->position, u->position);
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float edgelength = len3(tmp);
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float curvature=0;
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// find the "sides" triangles that are on the edge uv
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array(int) sides = 0;
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for (int i = 0; i<array_count(u->face); i++) {
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if (HasVertex(Face(M, u, i), vid)) {
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array_push(sides, u->face[i]);
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}
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}
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// use the triangle facing most away from the sides
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// to determine our curvature term
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for (int i = 0; i<array_count(u->face); i++) {
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float mincurv=1; // curve for face i and closer side to it
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for (int j = 0; j<array_count(sides); j++) {
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float dotprod = dot3(Triangle(M, u->face[i])->normal,
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Triangle(M, sides[j])->normal); // use dot product of face normals.
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float t = (1-dotprod)/2.0f;
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if (t < mincurv) {
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mincurv = t;
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}
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}
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if (mincurv > curvature)
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curvature = mincurv;
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}
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array_free(sides);
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// the more coplanar the lower the curvature term
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return edgelength * curvature;
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}
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static void ComputeEdgeCostAtVertex(struct mesh *M, struct vertex *v) {
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// compute the edge collapse cost for all edges that start
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// from vertex v. Since we are only interested in reducing
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// the object by selecting the min cost edge at each step, we
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// only cache the cost of the least cost edge at this vertex
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// (in member variable collapse) as well as the value of the
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// cost (in member variable objdist).
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if (array_count(v->neighbor) == 0) {
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// v doesn't have neighbors so it costs nothing to collapse
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v->collapse=-1;
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v->objdist=-0.01f;
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return;
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}
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v->objdist = 1000000;
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v->collapse=-1;
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// search all neighboring edges for "least cost" edge
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for (int i = 0; i<array_count(v->neighbor); i++) {
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float dist = ComputeEdgeCollapseCost(M, v, v->neighbor[i]);
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if(dist<v->objdist) {
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v->collapse=v->neighbor[i]; // candidate for edge collapse
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v->objdist=dist; // cost of the collapse
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}
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}
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}
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static void ComputeAllEdgeCollapseCosts(struct mesh *M) {
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// For all the edges, compute the difference it would make
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// to the model if it was collapsed. The least of these
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// per vertex is cached in each vertex object.
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for (int i = 0; i<M->n_vertex; i++) {
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ComputeEdgeCostAtVertex(M, Vertex(M, i));
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}
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}
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static void Collapse(struct mesh *M, int uid, int vid) {
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// Collapse the edge uv by moving vertex u onto v
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// Actually remove tris on uv, then update tris that
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// have u to have v, and then remove u.
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struct vertex *u = Vertex(M, uid);
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if(vid < 0) {
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// u is a vertex all by itself so just delete it
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RemoveVertex(M, uid);
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return;
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}
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array(int) tmp = 0;
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// make tmp a Array of all the neighbors of u
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for (int i = 0; i<array_count(u->neighbor); i++) {
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array_push(tmp, u->neighbor[i]);
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}
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// delete triangles on edge uv:
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for( int i = array_count(u->face); i--; ) {
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if (HasVertex(Face(M, u, i), vid)) {
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RemoveTriangle(M, u->face[i]);
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}
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}
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// update remaining triangles to have v instead of u
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for( int i = array_count(u->face); i--; ) {
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ReplaceVertex(M, u->face[i], uid, vid);
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}
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RemoveVertex(M, uid);
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// recompute the edge collapse costs for neighboring vertices
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for (int i = 0; i<array_count(tmp); i++) {
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ComputeEdgeCostAtVertex(M, Vertex(M, tmp[i]));
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}
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array_free(tmp);
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}
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static struct vertex *MinimumCostEdge(struct mesh *M) {
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// Find the edge that when collapsed will affect model the least.
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// This function actually returns a Vertex, the second vertex
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// of the edge (collapse candidate) is stored in the vertex data.
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// Serious optimization opportunity here: this function currently
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// does a sequential search through an unsorted Array :-(
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// Our algorithm could be O(n*lg(n)) instead of O(n*n)
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struct vertex *mn = NULL;
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for (int i = 0; i<M->n_vertex; i++) {
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struct vertex *v = Vertex(M, i);
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if (v->id >=0) {
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if (mn == NULL || v->objdist < mn->objdist) {
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mn = v;
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}
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}
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}
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return mn;
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}
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/*
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* The function ProgressiveMesh() takes a model in an "indexed face
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* set" sort of way. i.e. Array of vertices and Array of triangles.
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* The function then does the polygon reduction algorithm
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* internally and reduces the model all the way down to 0
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* vertices and then returns the order in which the
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* vertices are collapsed and to which neighbor each vertex
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* is collapsed to. More specifically the returned "permutation"
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* indicates how to reorder your vertices so you can render
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* an object by using the first n vertices (for the n
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* vertex version). After permuting your vertices, the
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* map Array indicates to which vertex each vertex is collapsed to.
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*/
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API void ProgressiveMesh(int vert_n, int vert_stride, const float *v, int tri_n, const int *tri, int *map, int *permutation) {
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struct mesh M;
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MeshInit(&M, vert_n, tri_n);
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// put input data into our data structures M
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const char * tmp = (const char *)v;
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for (int i=0;i<vert_n;i++, tmp += vert_stride ) {
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AddVertex(&M, (const float *)tmp);
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}
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for (int i=0;i<tri_n;i++) {
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AddTriangle(&M, &tri[i*3]);
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}
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ComputeAllEdgeCollapseCosts(&M); // cache all edge collapse costs
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for (int i = vert_n-1; i>=0; i--) {
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// get the next vertex to collapse
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struct vertex *mn = MinimumCostEdge(&M);
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// keep track of this vertex, i.e. the collapse ordering
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permutation[mn->id] = i;
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// keep track of vertex to which we collapse to
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map[i] = mn->collapse;
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// Collapse this edge
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Collapse(&M, mn->id, mn->collapse);
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}
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// reorder the map Array based on the collapse ordering
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for (int i = 0; i<vert_n; i++) {
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map[i] = (map[i]==-1)?0:permutation[map[i]];
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}
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// The caller of this function should reorder their vertices
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// according to the returned "permutation".
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MeshFree(&M);
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}
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/*
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* The MIT License (MIT)
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*
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* Copyright (c) 2014 Stan Melax
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* Copyright (c) 2020 Cloud Wu
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*
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* Permission is hereby granted, free of charge, to any person obtaining a copy
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* of this software and associated documentation files (the "Software"), to deal
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* in the Software without restriction, including without limitation the rights
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* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
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* copies of the Software, and to permit persons to whom the Software is
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* furnished to do so, subject to the following conditions:
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*
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* The above copyright notice and this permission notice shall be included in all
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* copies or substantial portions of the Software.
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*
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* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
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* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
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* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
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* SOFTWARE.
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*/
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